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Main Author: Akolekar, Harshal D.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.07803
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author Akolekar, Harshal D.
author_facet Akolekar, Harshal D.
contents Separated flow transition is a very popular phenomenon in gas turbines, especially low-pressure turbines (LPT). Low-fidelity simulations are often used for gas turbine design. However, they are unable to predict separated flow transition accurately. To improve the separated flow transition prediction for LPTs, the empirical relations that are derived for transition prediction need to be significantly modified. To achieve this, machine learning approaches are used to investigate a large number of functional forms using computational fluid dynamics-driven gene expression programming. These functional forms are investigated using a multi-expression multi-objective algorithm in terms of separation onset, transition onset, separation bubble length, wall shear stress, and pressure coefficient. The models generated after 177 generations show significant improvements over the baseline result in terms of the above parameters. All of the models developed improve the wall shear stress prediction by 40-70\% over the baseline laminar kinetic energy model. This method has immense potential to improve boundary layer transition prediction for gas turbine applications across several geometries and operating conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2409_07803
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Enhancing Accuracy of Transition Models for Gas Turbine Applications Through Data-Driven Approaches
Akolekar, Harshal D.
Fluid Dynamics
Separated flow transition is a very popular phenomenon in gas turbines, especially low-pressure turbines (LPT). Low-fidelity simulations are often used for gas turbine design. However, they are unable to predict separated flow transition accurately. To improve the separated flow transition prediction for LPTs, the empirical relations that are derived for transition prediction need to be significantly modified. To achieve this, machine learning approaches are used to investigate a large number of functional forms using computational fluid dynamics-driven gene expression programming. These functional forms are investigated using a multi-expression multi-objective algorithm in terms of separation onset, transition onset, separation bubble length, wall shear stress, and pressure coefficient. The models generated after 177 generations show significant improvements over the baseline result in terms of the above parameters. All of the models developed improve the wall shear stress prediction by 40-70\% over the baseline laminar kinetic energy model. This method has immense potential to improve boundary layer transition prediction for gas turbine applications across several geometries and operating conditions.
title Enhancing Accuracy of Transition Models for Gas Turbine Applications Through Data-Driven Approaches
topic Fluid Dynamics
url https://arxiv.org/abs/2409.07803